Abstract: Detection of nuclear reactions are accomplished through use of a solid-state detector that uses a hexagonal boron nitride configuration. Metallized areas for the hexagonal boron nitride have a metallized top and bottom area that is pixelated.

Abstract: Detection of nuclear reactions are accomplished through use of a solid-state detector that uses a hexagonal boron nitride configuration. Metallized areas for the hexagonal boron nitride have a metallized top and bottom area that is pixelated.

Abstract: A scintillator package includes a scintillator crystal, a first reflector layer directly surrounding a first area of a surface of the scintillator crystal, wherein the first reflector layer comprises a diffuse reflector, a second reflector layer directly over the first reflector layer, wherein the second reflector layer comprises a metal, and a package housing directly over the second reflector layer, wherein the package housing comprises a polymer with a reinforcing material, wherein the package housing is configured to optically expose a second area of the surface of the scintillator crystal.

Abstract: A downhole tool includes a housing a measurement device disposed in the housing. The measurement device includes a sensor and electronic circuitry configured to detect or process signals detected by the sensor. The housing, the sensor, or the electronic circuitry, or any combination thereof, includes a polymer matrix with integrated boron nitride nanotubes.

Abstract: A downhole tool includes a housing a measurement device disposed in the housing. The measurement device includes a sensor and electronic circuitry configured to detect or process signals detected by the sensor. The housing, the sensor, or the electronic circuitry, or any combination thereof, includes a polymer matrix with integrated boron nitride nanotubes.

Abstract: A technique facilitates use of radiation sampling techniques in subterranean formation environments or other environments. A radiation detector may be constructed utilize a scintillator package having a scintillating crystal. The scintillating crystal is combined with a reflector positioned to reflect light otherwise leaving a surface of the scintillating crystal. The reflector incorporates nano materials, e.g. nano particles or nano fibers, arranged to provide highly reflective properties. By way of example, the nano materials may be fabricated in a separate layer combined with the scintillating crystal or applied directly onto a surface of the scintillating crystal.

Abstract: A scintillator package includes a scintillator crystal, a first reflector layer directly surrounding a first area of a surface of the scintillator crystal, wherein the first reflector layer comprises a diffuse reflector, a second reflector layer directly over the first reflector layer, wherein the second reflector layer comprises a metal, and a package housing directly over the second reflector layer, wherein the package housing comprises a polymer with a reinforcing material, wherein the package housing is configured to optically expose a second area of the surface of the scintillator crystal.

Abstract: A radiation detector may include a housing and a scintillator body carried by the housing. The scintillator body may have an exterior surface with a plurality of surface scratches spiraling around the exterior surface. A photodetector may be coupled to the scintillator body.

Abstract: A radiation detector may include a housing and a scintillator body carried by the housing. The scintillator body may have an exterior surface with a plurality of surface scratches spiraling around the exterior surface. A photodetector may be coupled to the scintillator body.

Abstract: Methods and devices relating to a radiation detector comprising of a gas chamber having a cathode plate and a substrate separated by a gap. An array of nano-tips deposited on the substrate that forms an anode structure for electron charge collection. An external power source in communication with the cathode plate and the substrate, wherein the external power source is capable of generating a plurality of regions and each region includes an electric field near each nano-tip of the array of the nano-tips that results in initiating a radiation induced controlled discharge of electrons and ions from at least one gas or at least one gas mixture. Finally, the plurality of regions include multiple generated electric fields near tips of the array of nano-tips such as CNTs, that communicatively create a conductive path between the cathode plate and the substrate, the radiation detector is capable of determining at least one radiation property.

Abstract: Methods and devices relating to a radiation detector comprising of a gas chamber having a cathode plate and a substrate separated by a gap. An array of nano-tips deposited on the substrate that forms an anode structure for electron charge collection. An external power source in communication with the cathode plate and the substrate, wherein the external power source is capable of generating a plurality of regions and each region includes an electric field near each nano-tip of the array of the nano-tips that results in initiating a radiation induced controlled discharge of electrons and ions from at least one gas or at least one gas mixture. Finally, the plurality of regions include multiple generated electric fields near tips of the array of nano-tips such as CNTs, that communicatively create a conductive path between the cathode plate and the substrate, the radiation detector is capable of determining at least one radiation property.

Abstract: An electron acceleration portion of a Betatron having a vacuum chamber with an interior wall spaced from an exterior wall with a main electron orbit located approximate to the exterior wall and the interior wall. An electron injector has an anode structured and arranged adjacent a wall selected from the group consisting of the interior wall and the exterior wall that is shaped so as to not impede the main electron orbit. There is at least one electron deflection plate disposed approximate an anode end of the anode and the main electron orbit. There can be two electron deflection plates spaced apart that form a gap of a width effective to receive emitted electrons from the electron injector. Such that, there is a voltage potential between the two electron deflection plates that is effective to deflect emitted electrons towards the main electron orbit.

Abstract: A method of enabling mailpieces to be distributed and consulted in electronic form, including the steps of scanning each of the mailpieces and transmitting the images of the mailpieces to a first server; displaying the images on a first viewing screen associated with the first server, and assigning each of the images to a recipient by “dropping ” the image into one of the pigeonholes of a virtual sorting rack associated with the recipient and displayed on the first viewing screen or on a second viewing screen also associated with the first server; and displaying a dynamic dialogue box on at least one consultation screen of a final recipient.

Abstract: An electron acceleration portion of a Betatron having a vacuum chamber with an interior wall spaced from an exterior wall with a main electron orbit located approximate to the exterior wall and the interior wall. An electron injector has an anode structured and arranged adjacent a wall selected from the group consisting of the interior wall and the exterior wall that is shaped so as to not impede the main electron orbit. There is at least one electron deflection plate disposed approximate an anode end of the anode and the main electron orbit. There can be two electron deflection plates spaced apart that form a gap of a width effective to receive emitted electrons from the electron injector. Such that, there is a voltage potential between the two electron deflection plates that is effective to deflect emitted electrons towards the main electron orbit.

Abstract: A method of enabling mailpieces to be distributed and consulted in electronic form, said method comprising the following steps: scanning each of the mailpieces and transmitting the images of the mailpieces scanned in this way to a first server on which said images are stored; displaying said images stored on said first server on a first viewing screen associated with said first server, and assigning each of said images to a recipient by “dropping” said image into one of the pigeonholes of a virtual sorting rack associated with said recipient and displayed on said first viewing screen or on a second viewing screen also associated with said first server; and displaying a dynamic dialogue box on at least one consultation screen of a final recipient, said dynamic dialogue box including at least one counter whose value depends on the number of images that are assigned to the pigeonhole of said final recipient and that are accessible on said first server from said consultation screen via a local area network con